Application of Reverse Engineering Technology in Part Design for Shipbuilding Industry
References
- 1. 3D Measurement Solutions for Every Industry.
https://www.faro.com/metrology-3d-documentation-solutions-from-faro/3d-measurement-solutions-for-every-industry , dostęp: 29.11.2018. - 2. ABBAS, Mohd Azwan, et al. Improvements to the accuracy of prototype ship models measurement method using terrestrial laser scanner. Measurement, 2017, 100: 301-310.
- 3. ACKERMANN, S., et al. Digital photogrammetry for high precision 3D measurements in shipbuilding field. In: 6th CIRP International Conference on ICME-Intelligent Computation in Manufacturing Engineering. 2008.
- 4. ANWER, Nabil; MATHIEU, Luc. From reverse engineering to shape engineering in mechanical design. CIRP Annals, 2016, 65.1: 165-168.
- 5. BUONAMICI, Francesco, et al. Reverse engineering of mechanical parts: A template-based approach. Journal of Computational Design and Engineering, 2018, 5.2: 145-159.
- 6. DEJA, Mariusz, et al. Application of Rapid Prototyping Technology in the Manufacturing of Turbine Blade with Small Diameter Holes. Polish Maritime Research, 2018, 25.s1: 119-123.
- 7. GÓMEZ, A., et al. Manufacturing of custom-made parts for assembly of large aircraft components. Procedia engineering, 2015, 132: 1006-1013.
- 8. KACZYŃSKI, Piotr, et al. Leakage flow reduction in different configuration of labyrinth seal on a turbine blade tip. In: Journal of Physics: Conference Series. IOP Publishing, 2018. p. 012012.
- 9. KO, Kwang Hee, et al. Development of software for computing forming information using a component based approach. International Journal of Naval Architecture and Ocean Engineering, 2009, 1.2: 78-88.
- 10. KOELMAN, Herbert J. Application of a photogrammetry-based system to measure and re-engineer ship hulls and ship parts: An industrial practices-based report. Computer-Aided Design, 2010, 42.8: 731-743.
- 11. LI, Lingling, et al. An integrated approach of reverse engineering aided remanufacturing process for worn components. Robotics and Computer-Integrated Manufacturing, 2017, 48: 39-50.
- 12. MENNA, F.; TROISI, S. Low cost reverse engineering techniques for 3D modelling of propellers. International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 2010, 38. Part 5: 452-457.
- 13. NSRP ASE Ship Check Data Capture Follow-on Project (NSRP ASE 05-01) Final Report (FY06), 2007.
- 14. PARK, Jung Seo; SHIN, Jong Gye; KO, Kwang Hee. Geometric assessment for fabrication of large hull pieces in shipbuilding. Computer-Aided Design, 2007, 39.10: 870-881.
- 15. PAULIC, Matej, et al. Reverse engineering of parts with optical scanning and additive manufacturing. Procedia Engineering, 2014, 69: 795-803.
- 16. ROCA-PARDIÑAS, Javier, et al. Assessing planar asymmetries in shipbuilding from point clouds. Measurement, 2017, 100: 252-261.
- 17. TASSETTI, N.; MARTELLI, Michele; BUGLIONI, Gabriele. Reverse engineering techniques for trawler hull 3D modelling and energy efficiency evaluation. In: Proc of NAV 2015 18th International Conference on Ships and Shipping Research. 2015. p. 24-26.
- 18. Using Artec 3D scanning technology to keep naval ships in perfect condition.
https://www.artec3d.com/news/3d-scanning-reverse-engineering-for-navy , dostęp: 29.11.2018 - 19. WANG, Jun, et al. A framework for 3D model reconstruction in reverse engineering. Computers & Industrial Engineering, 2012, 63.4: 1189-1200.
- 20. ZHANG, Yu. Research into the engineering application of reverse engineering technology. Journal of Materials Processing Technology, 2003, 139.1-3: 472-475.
- 21. Geomagic Design X:
https://www.3dsystems.com/software/geomagic-design-x [accessed on January 22, 2019]. - 22. COSTA-JOVER, Agustí, et al. Using the terrestrial laser scanner and simple methodologies for geometrically assessing complex masonry vaults. Journal of Cultural Heritage, 2018,
https://doi.org/10.1016/j.culher.2018.10.003">https://doi.org/10.1016/j.culher.2018.10.003 .10.1016/j.culher.2018.10.003 - 23. GUARATO, Alexandre Zuquete, et al. Conversion of 3D scanned point cloud into a voxel-based representation for crankshaft mass balancing. The International Journal of Advanced Manufacturing Technology, 2018, 95.1-4: 1315-1324.
- 24. HOLST, Christoph, et al. Terrestrial Laser Scanner Two-Face Measurements for Analyzing the Elevation-Dependent Deformation of the Onsala Space Observatory 20-m Radio Telescope’s Main Reflector in a Bundle Adjustment. Sensors, 2017, 17.8: 1833.
- 25. ŠTALMACH, Ondrej, et al. Conversion of data from the laser scanner to the Ansys Workbench. In: MATEC Web of Conferences. EDP Sciences, 2019. p. 02003.
- 26. ZHANG, Hongyao; LI, Lun; ZHAO, Jibin. Robot automation grinding process for nuclear reactor coolant pump based on reverse engineering. The International Journal of Advanced Manufacturing Technology, 2019, 1-13.
Language: English
Page range: 126 - 133
Published on: Jul 12, 2019
Published by: Gdansk University of Technology
In partnership with: Paradigm Publishing Services
Publication frequency: 4 times per year
Related subjects:
© 2019 Mariusz Deja, Michał Dobrzyński, Marcin Rymkiewicz, published by Gdansk University of Technology
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.